Site description, experimental design and crop management

Strip cropping technique was introduced in 2017 at the MOnsampolo VEgetable organic Long-Term Experiment (MOVE-LTE) located in Monsampolo del Tronto (AP), coastal area of Central Italy (42°53′N, 13°48′E). MOVE-LTE is characterized by a typical thermo-Mediterranean climate and its soil is Typic Calcixerepts fine-loamy, mixed thermic one (USDA, 1996). The 30-year average monthly data for the temperature and precipitation in the MOVE-LTE are reported in Supplementary Figure S1 and compared with data recorded during the strip cropping experimental years. The mean annual temperature was 15.5°C in each experimental year. Except for May, in each month it was 1.5°C higher than the 30-year mean. We also recorded a peak of +4°C in November 2020 and some exceptional frosts in February 2018. The average rainfall during the three experimental years was 650 mm. It was +140 mm compared to the 30-year average value. This rainfall resulted from strong storm events occurred in November 2018 and March 2020, even if they were alternated with dry months. MOVE-LTE is a wide field of 2112 m² and it is divided into four equal rotational areas. Within this LTE, the crop diversification techniques are based on 4-year rotation and the use of cover crops was applied from 2001 (Supplementary Fig. S2; Canali et al., Reference Canali, Campanelli, Ciaccia, Leteo, Testani and Montemurro2013; Campanelli and Canali, Reference Campanelli and Canali2012). Nine plant species were cultivated annually (six for income and three for services provision (i.e., agroecological service crops) belonging to seven different botanical families. Every year, only two rotational areas were included in the 3-year (2017–2018; 2018–2019; 2019–2020) strip cropping experiments of this study. Specifically, the two experiments were carried out to test strip cropping (S) vs pure stand (P). The chosen crop combinations were faba bean (Vicia faba L., local cv ‘Fratterosa’)–tomato (Solanum Lycopersicum L., local cv ‘SAAB CRA’) and common wheat (Triticum aestivum, heterogeneous material)–zucchini (Cucurbita pepo, F1 ‘Galatea’). The selected species are widely cultivated in the Mediterranean test area and in particular, the botanical families adopted in these experiments were already included in the crop rotations the MOVE-LTE. Both, leguminous crops and cereals were cultivated as agroecological service crops before tomato and zucchini, respectively.

In the MOVE-LTE, two experiments were established: (1) faba bean–tomato; (2) wheat–zucchini. Each experiment is divided into two different sub-experiments to test vegetable crops (tomato or zucchini) in S vs vegetable crops in P stands, and grain crops (faba bean or wheat) in S vs grain crops in P stands. Each sub-experiment consisted of a non-randomized block design with three adjacent blocks and two replicated treatments (S and P stands) per each block. In fact, to keep the P stand separated from the S cropping, it was not possible to completely randomize the experiments. Each block included six plots, three plots for each treatment. The four sub-experiments were analyzed separately. Size of the plot for vegetable crops was 15.2 m², while for grain crops it was 14.2 m². The experimental design was repeated each year in two fields within the rotation of MOVE-LTE. The layout of the experiments is reported in Supplementary Figure S2 in.

Experiment 1. Hairy vetch of the existing rotation was replaced by faba bean to obtain a multiple cropping system based on faba bean–tomato. This experiment consisted of two sub-experiments with the same layout to test: (a) faba bean for dry grains in S with tomato vs faba bean for dry grain in P; (b) tomato in S with faba bean for dry grains vs tomato in P. Strips were 2.0 and 2.8 m wide for faba bean (dry grain production) and tomato, respectively. In the whole experimental area (both S and P stands) of the two sub-experiments, faba bean was sown in October with a density of 150 kg ha⁻¹. In S and P tomato areas, the faba bean was harvested in May for fresh pod production, while in the remaining experimental areas it was left for dry grain production until harvest (July). After harvest of fresh product, the faba bean residues were flattened by the In-Line Roller Crimper technology (ILRC; Canali et al., Reference Canali, Campanelli, Ciaccia, Leteo, Testani and Montemurro2013) and tomato was transplanted in May, with a density of 28,500 plant ha⁻¹ in both S and P, on the obtained mulch without soil tillage.

Experiment 2. Also this experiment consisted of two sub-experiments to test: (a) wheat grain in S with zucchini vs wheat grain in P stands; (b) zucchini in S with wheat grain vs zucchini in P stand. In the experimental field area, common wheat was sown in late October to early November at a density of 200 kg ha⁻¹. Strips were 2.0 and 2.8 m wide for wheat (dry grain production) and zucchini, respectively. In S and P zucchini areas, the wheat was terminated at flowering (April–May) by the ILRC, while in the remaining areas it was left for dry grain production until July. Zucchini was transplanted (13,400 plants ha⁻¹ both in P and S) on the wheat mulch without soil tillage. In 2019, zucchini was harvested in June, July and August, while only in June and July during the other experimental years.

Agronomic management practices adopted during the experimental years for the crops of both experiments are reported in Supplementary Table S1.

Measurements

At harvest dates, one square meter faba bean fresh pods, faba bean dry grain, wheat dry grain and their related crop aboveground residues were manually collected from each experimental plot. The same occurred both for tomato and zucchini residues at final harvesting time, collected from four tomato and three zucchini plants from each plot. Weeds were manually collected in an area of 0.25 m² per each plot, at each weeding operation and at the end of the crop harvest. Total weed biomass as the sum of the different sampling times per plot was considered in the study. Vegetable fruits were manually collected throughout the season. All mature tomato and zucchini fruits were collected sampling the four and three central crop plants from each plot, respectively. They were selected according to local market standards to obtain both fresh marketable and non-marketable yields. At each harvest time, the fruit samples collected at plot level were subsampled and frozen. Subsamples from different harvest times were combined to constitute the final fresh samples. Fresh biomass were dried at 105°C for 24 h to obtain the dry weight and then analyzed for nitrogen (N) concentration by a LECO Nitrogen analyzer model FP-528 (St. Joseph, MI, USA). Furthermore, carbon (C) concentrations in crop residues, non-marketable yield and weed biomass were assessed using a LECO TOC Analyzer, model RC-612 (LECO Corporation, 1987).

The effect on the dry grains faba bean was evaluated in terms of grain yield and 100-seed weight, on wheat in terms of grain yield, 1000-seed weight, hectoliter weight (ISO 7971-3, 2019) and gluten content (AACC Method 38–10.01, 1999), and on vegetable summer crops in terms of marketable yield, fruit weight and number of marketable fruits.

During the second and third experimental year, an in-depth study was carried out by measuring the soil mineral N (SMN, NO₃⁻-N + NH₄⁺-N, 0–30 cm soil depth, 3 soil core sampling per plot, combined to finally obtain one sample per plot for subsequent analyses), by collecting soil samples at 49 and 73 days after transplanting (DAT) in 2019 and 2020, respectively. These DAT corresponded to beginning of fruit setting and beginning of harvest for tomato, respectively, and with 26 and 30 DAT in 2019 and 2020 for zucchini, respectively, which corresponded with beginning of fruit setting in both years.

The SMN was extracted by 2 M KCl (1:10, w/v) and measured by continual flow colorimetry, according to Krom (Reference Krom1980) and Henriksen and Selmer-Olsen (Reference Henriksen and Selmer-Olsen1970) for NH₄⁺-N and NO₃⁻-N, respectively.

Evaluation of fusarium (Fusarium oxysporum f. sp. lycopersici) infection on tomato or oidium (Oidium spp.) on zucchini, two key diseases, was carried out in each treatment and in all plots, and on the same 16 and 13 selected plants for tomato and zucchini, respectively.

Data on fusarium symptoms were collected three times in each experimental year (2018: July 3rd, July 24th, August 20th; 2019: July 5th, July 26th, August 23th; 2020: July 15th, July 28th, August 17th), while oidium symptoms were assessed two times in each year (2018: July 3rd, July 24th; 2019: July 22th, August 22th; 2020: July 15th, August 3rd). The disease incidence was expressed as percentage of infected plants relative to the total number of plants observed. The severity index represents the mean symptom intensity (Madden and Hughes, Reference Madden and Hughes1999) and it was expressed assigning five levels of an empirical scale, from 0 (healthy plant) to 4 (100% of the infected leaves). The infection index or McKinney index (McKinney, Reference McKinney1923) includes both the incidence and severity of the disease. It expresses the weighted means of the disease as a percentage of the maximum possible level and it was calculated using the following equation:

$${\rm Infection\ index} = [ {\Sigma ( {d\times f} ) {\rm /\ }( {n\times D} ) } ] \times 100$$

where d is the level of empirical scale, f is the frequency of each level, n is the total number of plants examined and D is the highest level of the disease intensity that occurs on an empirical scale.

Advantage, competition and economic indices

The advantage of S cropping over the P system and the effect of competition between the two intercropped species were calculated for the 3 years of the two experiments as mean values of each treatment using the land equivalent ratio (LER) and competitive ratio (CR) indices.

The LER (Mead and Willey, Reference Mead and Willey1980) indicates the efficiency of S cropping in the use of environmental resources to obtained yield compared with the P system. Any value greater than 1.0 indicates a yield advantage for strip cropping. LER was calculated as

$${\rm LER} = \sum \left({\displaystyle{{Ysi} \over {Ypi}}} \right)$$

where Ys is the yield of each crop in the S cropping, and Yp is the yield of each crop in the P stand.

For each i-th crop, a ratio is computed to determine the partial LER for it. The partial LERs are then summed to achieve the total LER.

The CR (Willey and Rao, Reference Willey and Rao1980) was used as an indicator to evaluate the competitive ability of different crops in strip cropping. Considering the two crops in each experiment, it was calculated as

$${\rm CR\;crop}1 = \displaystyle{{{\rm Partial\;LERcrop}1} \over {{\rm Partial\;LER\;crop}2}} \times \displaystyle{{{\rm Pcrop}2} \over {{\rm Pcrop}1}}\;; \;\;\;{\rm CR\;crop}2 = \displaystyle{{{\rm Partial\;LERcrop}2} \over {{\rm Partial\;LER\;crop}1}} \times \displaystyle{{{\rm Pcrop}1} \over {{\rm Pcrop}2}}\;$$

where Pcrop1 is the sown proportion of crop 1 in intercropping with crop 2 and Pcrop2 is the sown proportion of crop 2 in intercropping with crop 1.

A CR value >1 for a crop indicates that it is more competitive than the other in the intercropping system (Zhang et al., Reference Zhang, Yang and Dong2011).

The same concepts and formulas of LER and CR were also applied to N uptake and organic C returned to soil.

According to Salehi et al. (Reference Salehi, Mehdi, Fallah, Kaul and Neugschwandtner2018), N-ABG-LER and N-LER were calculated for each experiment using N uptake (kg N ha⁻¹) of the aboveground crop biomass and yields, respectively, to determine the nutritional advantage of intercropping. The N-ABG-CR and N-CR were similarly calculated to evaluate the competitive ability of different crops in the use of N resources.

The effectiveness of the S cropping system in returning C to the soil was computed through C-LER using the amount of C input (Mg C ha⁻¹) from crop residues, mulch, non-marketable yield and weed biomass in each treatment of the two experiments. The greater or lesser contribution to soil C between the two intercropping crops was evaluated with C-CR calculation.

Gross margin (GM) was used to determine the profitability of both S and P of the following crop combinations: (i) faba bean for dry grain–faba bean for fresh pod production+tomato transplanting; (ii) common wheat–zucchini. The economic analysis was calculated each year and both in S and P systems as follows:

$${\rm GM} = \sum ( {\;( {Yi \times {\rm Pi}} ) -Ci} ) $$

where Yi is the marketable yield of the i-th crop, Pi is the market price for the i-th crop and Ci is the total direct expenses for the i-th crop.

To allow a comparison between S and P, GM was calculated considering: (a) 1 ha cultivated in S with the same widths (2.8 and 2.0 m) and management described in the experiments; (b) 1 ha cultivated in P stands in a proportion of 42% for one crop (faba bean for dry grain or common wheat) and 58% for the other one (faba bean for fresh pod production + tomato or zucchini). These percentages represent the total area included in all the strips in the intercropping system. The crop management in P was the same as reported in the experiments.

Yields and direct costs (Supplementary Tables S2 and S3) were those incurred in carrying out the experiments, while selling prices were set according to a team of organic farmers who reviewed the MOVE LTE procedures and results. They were: €1 kg⁻¹ for faba bean dry grains; €2 kg⁻¹ for faba bean fresh pods, tomatoes and zucchini; €0.45 kg⁻¹ for wheat grains.

Statistical analysis

Statistical analyses were performed with R software (R Core Team, 2021). Crop and soil variables described above, such as fruit (marketable and non-marketable) and grain yield, crop aboveground residues, weed biomass, marketable fruit and seed weight, marketable fruit numbers and SMN measurements for each sub-experiment, were statistically analyzed by analysis of variance (ANOVA). A mixed model using lme function of nlme R package (Pinheiro and Bates, Reference Pinheiro and Bates2022) was built with treatment (T, 2 levels: S—strip; P—pure), year (Y) and the interaction of T × Y as fixed effects. The block factor was included in the random part of the model with the block (B) nested within the rotational areas. Since the experimental layout was characterized by non-randomization, we introduced spatial correlation structures in the model to account for the lack of independence among samples (Pinheiro and Bates, Reference Pinheiro and Bates2000; Navarro-Miró et al., Reference Navarro-Miró, Blanco-Moreno, Ciaccia, Testani, Iocola, Depalo, Burgio, Kristensen, Hefner, Tamm and Bender2022). Models without and with different (exponential, Gaussian and spherical) spatial correlation structures were compared considering Akaike's and Bayesian information criteria. For each dependent variable, the selected best model was always without any spatial correlation structure. When necessary, data were transformed by the function y = log(x) or y = √x to ensure the normality and homoscedasticity of the residuals checked graphically and through statistical tests in R. We used shapiro.test function to test normality (Shapiro and Wilk, Reference Shapiro and Wilk1965) and leveneTest function from car package for homoscedasticity of the variance (Levene, Reference Levene and Olkin1960). Mean comparison was carried out according to post-hoc Tukey's test using the R package emmeans (Lenth, Reference Lenth2022). Reported means and standard errors are from non-transformed data.

The non-parametric clustered Wilcoxon rank-sum test was performed using the R package clusrank (Jiang et al., Reference Jiang, Lee, He, Rosner and Yan2020) to evaluate the effect of strip cropping on incidence, severity and infection index of fusarium and oidium diseases on tomato and zucchini, respectively, across the multiple years of the sub-experiments. In order to compare disease observations in both S and P treatments on the same date and in the same experiment block, data were clustered by observation date and experiment block.

Advantage, competition and economic indices described in 2.3 sub-paragraph were instead assessed across the multiple years of the two experiments evaluating average values and the coefficient of variation (CV), obtained by dividing the standard deviation by the mean, multiplied by 100.